Cationic amphiphilic peptides have the potential to function as agents for the treatment of microbial infections and cancer therapy. The cationic and hydrophobic parts of these molecules allow them to associate strongly with negatively charged bacterial or cancer cell membranes, thus exerting antimicrobial and anticancer activities through membrane disruption. Meanwhile, cyclometalated iridium(III) complexes such as fac-Ir(ppy)3 (ppy = 2-phenylpyridine) and fac-Ir(tpy)3 (tpy = 2-(4'-tolyl)pyridine) possess C3-symmetric structures and excellent photophysical properties as phosphorescence materials, which make them important candidates for use in biological applications such as chemosensors, biolabeling, living cell staining, in vivo tumor imaging, and anticancer agents. We recently reported on some regioselective substitution reactions of Ir(tpy)3 and Ir(ppy)3 at the 5'-position (p-position with respect to the C-Ir bond) on the 2-phenylpyridine ligands and their subsequent conversions to a variety of functional groups. We report here on the design and synthesis of amphiphilic and luminescent tris-cyclometalated Ir complexes in which cationic peptides are attached through alkyl chain linkers that work as inducers and detectors of cell death. Ir complexes containing cationic peptides such as a KKGG sequence and alkyl chain linkers of adequate length (C6 and C8) exhibit considerable cytotoxicity against cancer cells such as Jurkat, Molt-4, HeLa-S3, and A549 cells, and that dead cells are well stained with these Ir complexes. Furthermore, an Ir complex in which the KKGG peptide is attached through a C6 linker displayed lower cytotoxicity against normal mouse lymphocytes. Mechanistic studies suggest that Ir complexes containing the KKGG peptide interact with anionic molecules on the cell surface and/or membrane receptors to trigger the Ca(2+) dependent pathway and intracellular Ca(2+) response, resulting in necrosis accompanied by membrane disruption.